Fiber optic connector and method

ABSTRACT

A fiber optic connector including a ferrule surrounding an optical fiber and a hub engaging the ferrule. The hub includes a front portion having first and second surfaces and first and second tapered contact regions extending from the first and second surfaces to a front face. A housing includes an anti-rotation seat configured to engage the first and second surfaces, the anti-rotation seat including first and second angled contact surfaces positioned at a front of the anti-rotation seat. A spring within a chamber of the housing biases the ferrule through a bore in the front of the housing. The first tapered contact region of the hub engages the first contact surface, and the second tapered contact region engages the second contact surface when the hub and ferrule are in a first rotational position so that the optical fiber is maintained at a known orientation with respect to the connector. The tapered contact regions are planar surfaces sized smaller than the angled contact surfaces.

RELATED APPLICATION

This application claims benefit of provisional application Ser. No.60/562,696, filed Apr. 14, 2004, the disclosure of which is incorporatedby reference.

TECHNICAL FIELD

The present invention relates to fiber optic connectors for use in anoptical fiber signal transmission system, and to methods for assemblingsuch fiber optic connectors.

BACKGROUND

Fiber optic cables are used in the telecommunication industry totransmit light signals in high-speed data and communication systems. Astandard fiber optic cable includes a fiber with an inner lighttransmitting optical core. Surrounding the fiber is an outer protectivecasing.

A fiber terminates at a fiber optic connector. Connectors are frequentlyused to non-permanently connect and disconnect optical elements in afiber optic transmission system. There are many different fiber opticconnector types. Some of the more common connectors are FC and SCconnectors. Other types of connectors include ST and D4-type connectors.

A typical SC fiber optic connector includes a housing having a front endpositioned opposite from a rear end. The front end of the SC connectorhousing is commonly configured to be inserted within an adapter. Anexample adapter is shown in U.S. Pat. No. 5,317,663, assigned to ADCTelecommunications, Inc. The SC connector typically further includes aferrule that is positioned within the front and rear ends of thehousing, and adjacent the front end. The ferrule is axially moveablerelative to the housing, and is spring biased toward the front of theconnector. The fiber optic cable has an end that is stripped. Thestripped end includes a bare fiber that extends into the connector andthrough the ferrule.

A connector, such as the connector described above, is mated to anotherconnector within an adapter like the adapter of U.S. Pat. No. 5,317,663.A first connector is received within the front portion of the adapter,and a second fiber is received within the rear portion of the adapter.When two connectors are fully received within an adapter, the ferrules(and hence the fibers internal to the ferrule) contact or are in closeproximity to each other to provide for signal transmission between thefibers. A further SC connector is shown in U.S. Pat. No. 6,428,215,assigned to ADC Telecommunications, Inc. Another connector and matingadapter is shown in U.S. Pat. No. 6,142,676, also assigned to ADCTelecommunications, Inc.

Rotational misalignment of a ferrule with respect to a connector axiscan cause mis-engagement between the ferrule and a ferrule of anotherconnector, thereby contributing to signal loss. This problem isespecially acute for angled physical contact connectors. An angledphysical contact (APC) connector includes a ferrule and fiber with endfaces that are polished to a non-perpendicular angle (for example, 8degrees to a perpendicular plane) with respect to the longitudinal axisof the connector. APC connectors are discussed in U.S. Pat. No.5,734,769, assigned to ADC Telecommunications, Inc. The orientation ofthe end face must be maintained with a high degree of precision so thatthe angled end face of the optic fiber and associated ferrule correctlyengage an end face of an optic fiber and associated ferrule of anotherangled physical contact connector. Even a few degrees of misalignmentcan cause significant signal loss.

SUMMARY

The present invention concerns fiber optic connectors having a springbiased ferrule and hub assembly held within the connector. The hubincludes an anti-rotation portion which engages a complementary-shapedanti-rotation seat of the connector. The anti-rotation seat furtherincludes at least first and second contact surfaces, and theanti-rotation portion of the hub includes first and second matingcontact surfaces which maintain the end face of the optic fiber andassociated ferrule at a specific rotational angle with respect to thelongitudinal axis of the connector when the ferrule is in its restingposition. Further, when the ferrule is pushed back into the connectorand then allowed to return to its resting position, the contact surfacesre-engage to return the end face of the optic fiber and associatedferrule to the desired orientation. The contact surfaces are sized andshaped to allow the ferrule to return to its resting position withoutdamaging the connector parts, such as due to sharp edges. Also, thecontact surfaces are sized and shaped to only allow the ferrule toextend from the connector within a range that allows connection to otherconnectors, so that the ferrule is not extended too far or too littlewhen mated to another connector.

One aspect of the invention relates to a fiber optic connector includingan optical fiber, a ferrule surrounding the optical fiber, a hubretainably engaging the ferrule, wherein the hub includes a frontportion having first and second surfaces, and first and second taperedcontact regions at an angle with respect to a longitudinal axis of theconnector, a housing defining an anti-rotation seat configured to engagethe first and second surfaces of the front portion of the hub, theanti-rotation seat including first and second contact surfacespositioned at a front of the anti-rotation seat adjacent a bore definedby the housing through which the ferrule extends, and a spring disposedwithin a chamber defined by the housing and coupled to the anti-rotationseat, the spring biasing the ferrule through the bore of the housing,wherein the first tapered contact region of the hub engages the firstcontact surface and the second tapered contact region engages the secondcontact surface when the hub and ferrule are in a first rotationalposition relative to the housing so that an end of the optical fiber ismaintained at a known orientation with respect to the longitudinal axisof the connector. The tapered contact regions on the hub are preferablyplanar surfaces, preferably smaller than the contact surfaces of thehousing. In one preferred embodiment, three tapered contact regions andthree contact surfaces are provided.

Another aspect of the invention relates to a hub and ferrule assemblyfor a fiber optic connector including a ferrule configured to surroundan optical fiber, and a hub retainably engaging the ferrule, wherein thehub includes a front portion having first and second surfaces and firstand second tapered contact regions at an angle with respect to alongitudinal axis extending through a center of the hub and ferruleassembly, wherein the first tapered contact region is positioned toengage a first contact surface on the fiber optic connector and thesecond tapered contact region is positioned to engage a second contactsurface on the fiber optic connector. The tapered contact regions on thehub are preferably planar surfaces, preferably smaller than the matingcontact surfaces in the connector. In one preferred embodiment, threetapered contact regions are provided.

Yet another aspect of the invention relates to a fiber optic connectorhousing including an exterior body configured to be received in a fiberoptic adapter, a cavity defined by a rear portion of the connectorhousing, an anti-rotation seat coupled to the cavity, the anti-rotationseat including a plurality of longitudinally extending surfaces, andfirst and second angled contact surfaces positioned at a front of theanti-rotation seat adjacent a bore; the first and second angled contactsurfaces being spaced apart around a longitudinal axis of the connectorhousing. In one preferred embodiment, three contact surfaces areprovided.

Another aspect of the invention relates to a fiber optic connectorincluding an optical fiber, a ferrule surrounding the optical fiber, ahub retainably engaging the ferrule, the hub including an anti-rotationportion, a housing defining an anti-rotation seat configured to engagethe anti-rotation portion of the hub, a spring disposed within a chamberdefined by the housing and coupled to the anti-rotation seat, the springbiasing the ferrule through the bore of the housing, and an alignmentarrangement formed by the connector, the alignment arrangement includingfirst and second tapered contact regions formed on one of the hub andthe housing, and also including first and second contact surfaces formedon the other of the hub and the housing, wherein the first taperedcontact region engages the first contact surface and the second taperedcontact region engages the second contact surface when the hub andferrule are in a first rotational position relative to the housing sothat an end of the optical fiber is maintained at a known orientationwith respect to the longitudinal axis of the connector. The taperedcontact regions are preferably planar surfaces, and preferably smallerthan the contact surfaces. In one preferred embodiment, three taperedcontact regions and three contact surfaces are provided.

Yet a further aspect of the invention relates to a method for using afiber optic connector comprising steps of: providing a ferrulesurrounding an optical fiber with a hub retainably engaging the ferrule,the hub including opposing first and second tapered contact portions;providing a housing including a first contact surface positioned toengage the first tapered contact portion and a second contact surfacepositioned to engage the second tapered contact portion; pushing theferrule back to disengage the first and second tapered portions of thehub from the first and second contact surfaces of the housing; andreleasing the ferrule so that the first tapered contact portion engagesthe first contact surface and the second tapered contact portion engagesthe second contact surface, thereby retaining the optical fiber at aknown orientation with respect to the longitudinal axis of theconnector. The tapered contact regions are preferably planar surfaces,and preferably smaller than the contact surfaces. Preferably, threetapered contact portions and three contact surfaces retain the opticalfiber at the known orientation.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective few of an embodiment of a fiber optic connectorin accordance with the present invention.

FIG. 2 is an exploded view in perspective of the connector shown in FIG.1.

FIG. 3 is a cross-sectional side view of the connector of FIG. 1.

FIG. 4 is an enlarged cross-sectional side view of the front end of theconnector of FIG. 3.

FIG. 5 is a rear end view of the front housing of the connector.

FIG. 6 is a front end view of the front housing of the connector.

FIG. 7 is a front end view of the hub of the connector.

FIG. 8 shows in exploded view one pair of the mating contact surfaces ingreater detail.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

Reference will now be made in detail to exemplary aspects of the presentinvention that are illustrated in the accompanying drawings. Whereverpossible, the same reference numbers will be used throughout thedrawings to refer to the same or like parts.

FIGS. 1-8 illustrate an example embodiment of a connector 100 made inaccordance with the present invention. The connector 100 is of the SCtype. The connector 100 includes a front housing 110, a rear housing140, and a boot 150 with a bore 152. A grip 156 fits over the fronthousing 110, and the rear housing 140. The boot 150 fits into a rear end158 of the grip 156. Also included in the connector 100 is a hub/ferruleassembly 120 with a hub 122 and a ferrule 124. The hub 122 includes ananti-rotation portion 128 and an elongated cylindrical rear portion 123.The hub 122 is connected to the ferrule 124, such as with adhesive or aninterference fit. A spring 130 is also provided. A fiber optic cable 101is shown including a fiber 102 and a jacket 103.

The connector 100 is tunable by rotating the front housing 110 relativeto the rear housing 140. Once the grip 156 is positioned over the frontand rear housing 110, 140, the front housing 110 can no longer berotated relative to the rear housing 140. In order to rotate the fronthousing 110 relative to the rear housing 140, the hub 122 must be pushedback out of engagement with the front housing 110.

Disposed within the rear housing 140 is an anti-rotation seat 112 and acavity 114. The anti-rotation portion 128 of the hub 122 is slidinglyengaged along the longitudinal axis 200 in the anti-rotation seat 112.The anti-rotation portion 128 of the hub 122 includes an exteriorsurface of hub 122 extending parallel to the axis 200 having aconfiguration which does not allow rotation when the anti-rotationportion 128 of the hub 122 is mated with the anti-rotation seat 112. Inthe illustrated embodiment, the anti-rotation portion 128 of the hub 122includes a plurality of surfaces defining a bread loaf shape. Inparticular, three planar and perpendicularly arranged surfaces 129 areprovided defining generally three sides of the hub 122. A fourth surface131 is generally rounded (see FIG. 7), thereby defining the bread loafshape. The anti-rotation seat 112 is provided with a similar profile formating with the anti-rotation portion 128. Further details regarding thetunability feature and the anti-rotation feature of the connector 100are described and shown in U.S. Pat. No. 6,428,215, the disclosure ofwhich is hereby incorporated by reference.

The spring 130 surrounds the elongated cylindrical rear portion 123 ofthe hub 122. The spring is captured between the anti-rotation portion128 and a surface 146 of the rear housing 140. The spring 130 functionsto bias the ferrule 124 in a forward direction through a front bore 116of the front housing 110. The elongated cylindrical rear portion 123 ofthe hub 122 extends into the cavity 114 of the front housing 110.

The complementary fit between the anti-rotation seat 112 and theanti-rotation portion 128 is designed to maintain the ferrule 124 in aspecified orientation with respect to the longitudinal axis 200 of theconnector 100. However, small variations in tolerances between theanti-rotation seat 112 and the anti-rotation portion 128 may cause theferrule 124 to become misaligned a few degrees with respect to thelongitudinal axis 200, thereby causing the face 125 of the ferrule 124to be slightly misaligned, increasing the insertion loss when theconnector 100 is mated to another connector through an adapter. Suchmisalignment can occur during initial assembly. Such misalignment canalso occur when an end face of an APC connector is mated with an endface of another APC connector, and then one connector is removed. Thespring bias returns the ferrule 124 of the hub 122 to the frontposition. The longitudinally extending surfaces of the anti-rotationportion 128 and the anti-rotation seat 112 maintain the generalrotational positions of the hub 122 and the front housing 110, but smallvariations may be introduced. If not corrected, the next connection ofthe connector may result in rotationally misaligned end faces. Theangled end face 125 is shown in FIGS. 3 and 4.

Referring now to FIGS. 3-8, the alignment features of connector 100 areshown. The front housing 110 includes a plurality of contact surfaces220, 221, 222. The contact surfaces 220, 221, 222 on the housing 110engage mating contact regions 214, 215, 216 on the hub 122. Preferablythe contact surfaces 220, 221, 222 are angled at a 45-degree anglerelative to the longitudinal axis 200. The contact regions 214, 215, 216on the hub 122 are smaller planar surfaces also angled at a 45-degreeangle relative to the longitudinal axis 200.

In the preferred embodiment, three mating contact surfaces 220, 221, 222and contact regions 214, 215, 216, are provided on the connector 100.Two mating surfaces can also be utilized, if desired. Alternatively,more than three mating surfaces can be provided. Unused mating surfacescan be provided if greater numbers of surfaces on one of the hub 122 orthe front housing 110 are provided. Depending on the relative positionson the hub 122 and the front housing 110, only three of the contactregions 214, 215, 216 are used. The other contact regions 214 a, 215 a,216 a are not used unless the connector is tuned.

As shown, the contact surfaces 220, 221, 222 are equally spaced aboutthe longitudinal axis 200. Similarly, the contact regions 214, 215, 216have center portions that are also equally spaced about the longitudinalaxis 200.

By engagement of the respective pairs of angled contact surfaces andcontact regions, alignment of the ferrule 124 relative to the housing110 is provided. This alignment is greater than can be provided by thelongitudinally extending sliding surfaces of the anti-rotation portion128 and the anti-rotation seat 112.

As shown, the contact regions 214, 215, 216 are smaller than the contactsurfaces 220, 221, 222. If the contact regions 214, 215, 216 were toolarge, such as if they are similarly sized relative to the contactsurfaces 220, 221, 222, small angle variations during manufacture couldcause drastic variations in the amount of extension of ferrule 124. Ifthe ferrule 124 extended too far when mated to another connector, damageto the ferrules or connectors could occur. If the ferrule did not extendenough, poor signal transmission from connector to connector wouldresult. Alternatively, if the contact regions 214, 215, 216 are quitesmall, such that a fairly sharp edge is defined, damage to the fronthousing 110 can occur, such as when relatively larger springs 130 areused. The connector could become damaged if the hub or housing isengaged with too much force by a sharp edge, such as in the case whenplastic parts are used.

As one example, the hub 122 is made from metal, such as F/N 001 nickelsilver CDA 792, and the front housing 110 is made from plastic, such asF/N 001 U1 tem. Contact surfaces 220, 221, 222 are about 0.036 incheslong at the midpoint (dimension A in FIG. 5) and are angled 45 degrees±1 degree to the longitudinal axis 200. Contact surfaces 220, 221, 222are smaller at the ends, at about 0.014 inches (dimension B). The viewof FIG. 5 shows surfaces 220, 221, 222 at an angle. (Compare also to thecross-section of FIG. 4). Dimensions A and B noted above are takenparallel to the direction of extension of each surface. See also FIG. 8.

For an SC type connector in this example, it has been found that contactregions 214, 215, 216 of a length of about 0.0085 inches to 0.0100inches (dimension C in FIG. 7) at 45 degrees ±1 degree to the axis 200result in appropriate mating with the front housing 110, without causingdeformation of the front housing 110 or too much variation in theextension of the ferrule 124 as the angles on contact surfaces 220, 221,222 vary plus or minus 1 degree. In FIG. 7, contact regions 214, 215,216 are at an angle. Dimension C is parallel to the direction ofextension. See also FIG. 8. This results in a variation of extension ofthe ferrule of 0.00130 inches. With an SC connector designed as notedabove, an overall ferrule variation of extension of 0.014 inches isachieved. The dimension of 0.014 inches is an industry accepted ferrulevariation resulting in proper connections with mating connectors.

In the preferred embodiment, contact regions 214, 215, 216 are planarand smaller than contact surfaces 220, 221, 222.

Variations in the angle for the mating contact surfaces are possible.The illustrated example shows 45 degree angles from a plane transverseto the longitudinal axis. Other angles can be used such as 60 degrees.However, for the greater angles, greater variation in ferrule extensionmay be noticed as variations occur during manufacturing for the preciseangles and locations of the mating contact surfaces.

By utilizing three equally spaced contact surfaces 220, 221, 222, matedwith contact regions 214, 215, 216, less tilting of the ferrule 124relative to the longitudinal axis 200 occurs. The effect of threeequally spaced mating surfaces is similar to a three-legged stool or atripod. Three surfaces are advantageous over two, because they do notprovide any centering effect in a direction parallel to the twosurfaces. Increasing the number of mating surfaces can further reducetilting effects if more than three surfaces are mated. It is to beappreciated that the angled surfaces on hub 122 are not all equallysized. However, the effect of having three of them (214, 215, 216 or 214a, 215 a, 216 a) mate with surfaces 220, 221, 222 is to create a tripodeffect.

Some fiber optic connectors are tunable by unseating the ferrule andassociated hub from the anti-rotation seat. The ferrule and associatedhub is pushed back from the resting position by pressing the ferruleback into the connector. The anti-rotation portion of the hub clears thecomplementary-shaped anti-rotation seat of the connector. In thisposition, the ferrule can be rotated about a connector axis to thedesired rotational alignment that minimizes signal loss. The ferrule canthen be released, allowing the anti-rotation portion of the hub tore-engage the anti-rotation seat, thereby preventing further rotationthat may cause the connector to become un-tuned. In a connector of thisstyle, the contact surfaces 220, 221, 222 would similarly engage thecontact regions 214, 215, 216 to align the ferrule to a precise positionfor the new tuned location. After the ferrule is pushed back so that thehub disengages from the angled contact surfaces such as when aconnection to another connector occurs, and then the connector isdisconnected, the ferrule is then realigned with front housing by thereengagement of the contact surfaces 220, 221, 222 and the contactregions 214, 215, 216.

The above specification, examples and data provide a completedescription of the manufacture and of the invention. Since manyembodiments of the invention can be made without departing from thespirit and scope of the invention, the invention resides in the claimshereinafter appended.

1. A fiber optic connector comprising: an optical fiber; a ferrulesurrounding the optical fiber; a hub retainably engaging the ferrule,the hub including an anti-rotation portion; a housing defining ananti-rotation seat configured to engage the anti-rotation of the hub; aspring disposed within a chamber defined by the housing and coupled tothe anti-rotation seat, the spring biasing the ferrule through the boreof the housing; an alignment arrangement formed by the connector, thealignment arrangement including first, second, and third contactportions formed on one of the hub and the housing, and also includingfirst, second, and third angled contact surfaces formed on the other ofthe hub and the housing; wherein the first contact portion engages thefirst angled contact surface, the second contact portion engages thesecond angled contact surface, and the third contact portion engages thethird angled contact surface so that an end of the optical fiber ismaintained at a known orientation with respect to the longitudinal axisof the connector; wherein the first, second, and third angled surfacesare disposed around the longitudinal axis of the connector.
 2. Theconnector of claim 1, wherein the first, second, and third contactportions each define planar surfaces.
 3. A hub and ferrule assembly fora fiber optic connector, the assembly comprising: a ferrule configuredto surround an optical fiber; and a hub retainably engaging the ferrule,wherein the hub includes a front portion having first and secondsurfaces and first, second and third tapered contact regions extendingfrom the first and second surfaces to a front face of the hub at anangle with respect to a longitudinal axis extending through a center ofthe hub and ferrule assembly, wherein the first tapered contact regionis positioned to engage a first angled contact surface on the fiberoptic connector, the second tapered contact region is positioned toengage a second angled contact surface on the fiber optic connector, andthe third tapered contact region is positioned to engage a third angledcontact surface on the fiber optic connector, wherein the first, secondand third contact regions have surface portions which are equally spacedabout the longitudinal axis.
 4. A fiber optic connector housingcomprising: an exterior body configured to be received in a fiber opticadapter; a cavity defined by a rear portion of the connector housing; ananti-rotation seat coupled to the cavity, the anti-rotation seatincluding a plurality of longitudinally extending surfaces; and first,second and third angled contact surfaces positioned at a front of theanti-rotation seat adjacent a bore, wherein the first, second and thirdangled contact surfaces include surface portions equally spaced around alongitudinal axis of the connector housing.
 5. A fiber optic connectorcomprising: an optical fiber; a ferrule surrounding the optical fiber; ahub retainably engaging the ferrule, wherein the hub includes a frontportion having first and second surfaces and first and second taperedcontact regions extending from the first and second surfaces to a frontface of the hub at an angle with respect to a longitudinal axis of theconnector; a housing defining an anti-rotation seat configured to engagethe first and second surfaces of the front portion of the hub, thehousing including first and second angled contact surfaces positioned ata front of the anti-rotation seat adjacent a bore defined by the housingthrough which the ferrule extends; and a spring disposed within achamber defined by the housing and coupled to the anti-rotation seat,the spring biasing the ferrule through the bore of the housing; whereinthe first tapered contact region of the hub engages the first angledcontact surface and the second tapered contact region engages the secondangled contact surface when the hub and ferrule are in a firstrotational position relative to the housing so that an end of theoptical fiber is maintained at a known orientation with respect to thelongitudinal axis of the connector; wherein the first and second taperedcontact regions define angled surfaces less than or equal to 0.0100inches long and greater than or equal to 0.0085 inches long.
 6. Theconnector of claim 5, wherein the anti-rotation seat includes a thirdangled contact surface, wherein the hub includes a third tapered contactregion extending at the angle, the first, second, and third angledcontact surfaces equally spaced about the longitudinal axis of theconnector.
 7. The connector of claim 5, wherein end faces of the ferruleand the optical fiber are angled with respect to the longitudinal axisof the connector.
 8. The connector of claim 5, wherein the first andsecond angled contact surfaces are between about 0.20 and 0.30 as longas the first and second angled contact surfaces.
 9. An SC fiber opticconnector comprising: an optical fiber; a ferrule surrounding theoptical fiber; a metallic hub retainably engaging the ferrule, the hubincluding an anti-rotation portion; a plastic housing defining ananti-rotation seat configured to engage the anti-rotation portion of thehub; a spring disposed within a chamber defined by the housing andcoupled to the anti-rotation seat, the spring biasing the ferrulethrough the bore of the housing; and an alignment arrangement formed bythe connector, the alignment arrangement including first and secondtapered contact regions formed on one of the hub and the housing, andalso including first and second angled contact surfaces formed on theother of the hub and the housing; wherein the first tapered contactregion engages the first angled contact surface and the second taperedcontact region engages the second angled contact surface when the huband ferrule are in a first rotational position relative to the housingso that an end of the optical fiber is maintained at a known orientationwith respect to the longitudinal axis of the connector; wherein thefirst and second tapered contact regions define angled surfaces lessthan or equal to 0.0100 inches long and greater than or equal to 0.0085inches long.
 10. The connector of claim 9, wherein the alignmentarrangement further includes a third tapered contact region, and a thirdangled contact surface, wherein the third tapered contact region engagesthe third angled contact surface when the hub and ferrule are in thefirst rotational position.
 11. A method for using a fiber opticconnector comprising steps of: providing a ferrule surrounding anoptical fiber with a hub retainably engaging the ferrule, the hubincluding opposing first and second tapered contact portions; providinga housing including a first angled contact surface positioned to engagethe first tapered portion and a second angled contact surface positionedto engage the second tapered contact portion, wherein the first andsecond tapered contact portions are angled surfaces less than half aslong as the first and second angled contact surfaces; pushing theferrule back to disengage the first and second tapered contact portionsof the hub from the first and second angled contact surfaces of thehousing; and releasing the ferrule so that the first tapered contactportion engages the first angled contact surface and the second taperedcontact portion engages the second angled contact surface, therebyretaining the optical fiber at a known orientation with respect to thelongitudinal axis of the connector.
 12. The method of claim 11, furthercomprising steps of: connecting the connector to a second connector sothat the optical fiber matingly engages a second optical fiber in thesecond connector, thereby causing the hub to be pushed back and thefirst tapered contact portion to disengage from the first angled contactsurface and the second tapered contact portion to disengage from thesecond angled contact surface; and disconnecting the connector from thesecond connector so that the first tapered contact portion re-engagesthe first angled contact surface and the second tapered contact portionre-engages the second angled contact surface, thereby retaining theoptical fiber at the known orientation.
 13. An SC fiber optic connectorcomprising: an optical fiber; a ferrule surrounding the optical fiber; ahub retainably engaging the ferrule, the hub including an anti-rotationportion; a housing defining an anti-rotation seat configured to engagethe anti-rotation portion of the hub; a spring disposed within a chamberdefined by the housing and coupled to the anti-rotation seat, the springbiasing the ferrule through the bore of the housing; and an alignmentarrangement formed by the connector, the alignment arrangement includinga plurality of tapered contact regions formed on one of the hub and thehousing, and also including a plurality of angled contact surfacesformed on the other of the hub and the housing, the angled contactsurfaces and the tapered contact regions being spaced from alongitudinal axis of the connector; wherein the tapered contact regionsengage the angled contact surfaces when the hub and ferrule are in afirst rotational position relative to the housing so that an end of theoptical fiber is maintained at a known orientation with respect to thelongitudinal axis of the connector; wherein the tapered contact regionsand the angled contact surfaces are positioned at 45 degree angles,wherein the ferrule extends from the connector over a range of 0.00130inches as the angles are varied plus or minus 1 degree.
 14. Theconnector of claim 13, wherein a first tapered contact region of theplurality of tapered contact regions engages a first angled contactsurface of the plurality of contact surfaces, wherein a second taperedcontact region of the plurality of tapered contact regions engages asecond angled contact surface of the plurality of contact surfaces,wherein a third tapered contact region of the plurality of contactregions engages a third angled contact surface of the plurality ofcontact surfaces, wherein the first, second and third tapered contactregions, and the first, second and third contact surfaces includeportions which are equally spaced about the longitudinal axis.